-
[197] Miniature Li+ solvation by symmetric molecular design for practical and safe Li-metal batteries [Nature Energy, 2025]J. Jang, C. Wang, G. Kang, C. Han, J. Han, J.-S. Shin, S. Ko, G. Kim, J. Baek, H.-T. Kim, H. Lee, C. B. Park, D.-H. Seo, Y. Li* & J. Kang*
https://doi.org/10.1038/s41560-025-01733-9 -
[196] Concurrent electrode–electrolyte interfaces engineering via nano-Si3N4 additive for high-rate, high-voltage lithium metal batteries [Energy & Environmental Science, 18, 3148 (2015)
J. Kim, D. G Lee, J. H. Lee, S. Kim, C.-Y. Park, J. Y. Lee, H. Kwon, H. Cho, J. Lee, D. Son, H.-T. Kim, N.-S. Cho*, T. K. Lee* and J. Lee*
DOI: 10.1039/D4EE03862B -
![Solvation Structure Engineering via Inorganic–Organic Composite Layer for Corrosion-Resistant Lithium Metal Anodes in High-Concentration Electrolyte [Advanced Energy Materials, 15, 2403944 (2025)]](/files/boards/board_publications/12f0f8e3e8b0878d66c1cc43bd78e613.jpg)
[195] Solvation Structure Engineering via Inorganic–Organic Composite Layer for Corrosion-Resistant Lithium Metal Anodes in High-Concentration Electrolyte [Advanced Energy Materials, 15, 2403944 (2025)]Youngil Roh, Hyeokjin Kwon, Jaewon Baek, Changhoon Park, Seongyeong Kim, Kahee Hwang, A Reum Ha, Seongmin Ha, Jongchan Song, Hee-Tak Kim*
https://doi.org/10.1002/aenm.202403944 -
![Moderately Solvating Electrolyte with Fluorinated Cosolvents for Lean-Electrolyte Li–S Batteries [Advanced Energy Materials, 15, 2403828 (2025)]](/files/boards/board_publications/57ea7d049b028112f9d6a50f2cf808ce.jpg)
[194] Moderately Solvating Electrolyte with Fluorinated Cosolvents for Lean-Electrolyte Li–S Batteries [Advanced Energy Materials, 15, 2403828 (2025)]Ilju Kim, Sejin Kim, Hannah Cho, Jinkwan Jung, Hyeokjin Kwon, Dongwoo Kim, Yewon Shin, Hee-Tak Kim*
https://doi.org/10.1002/aenm.202403828 -
![Insight into the Impact of Electrolyte on Passivation of Lithium–Sulfur Cathodes [Advanced Materials Interfaces, 12 2400632 (2025)]](/files/boards/board_publications/97ef114b678cb462b6e37ed34412d6c7.jpg)
[193] Insight into the Impact of Electrolyte on Passivation of Lithium–Sulfur Cathodes [Advanced Materials Interfaces, 12 2400632 (2025)]Walter Cistjakov, Johanna Hoppe, Jinkwan Jung, Fridolin Röder, Hee‐Tak Kim, Ulrike Krewer*
https://doi.org/10.1002/admi.202400632 -
![Boosting the kinetics of bromine cathode in Zn–Br flow battery by enhancing the electrode adsorption of the droplet of bromine sequestration agent/polybromides complex [Journal of Power Sources, 620, 235219 (2024)]](/files/boards/board_publications/914a5b44e59a523de635f1d32844e989.jpg)
[192] Boosting the kinetics of bromine cathode in Zn–Br flow battery by enhancing the electrode adsorption of the droplet of bromine sequestration agent/polybromides complex [Journal of Power Sources, 620, 235219 (2024)]Yong-Hee Lee, Kyungjae Shin, Jaewon Baek, Hee-Tak Kim*
https://doi.org/10.1016/j.jpowsour.2024.235219 -
[191] Improving anion exchange membrane fuel cell performance via enhanced ionomer–carbon interaction in cathode catalyst layers with carbon-supported Pt catalyst using a pyrene carboxyl acid coating [Applied Catalysis B: Environment and Energy, 357, 124321 (20Jonghyun Hyun, Hojin Lee, Gisu Doo, Dong Wook Lee, Euntaek Oh, Jeesoo Park, Kyunghwa Seok, Jung Hwan Kim, Chulsung Bae, Hee-Tak Kim*
https://doi.org/10.1016/j.apcatb.2024.124322 -
![Addressing electrode passivation in lithium–sulfur batteries by site‐selective morphology‐controlled Li2S formation [EcoMat, 6, e12438 (2024)]](/files/boards/board_publications/c903aa0d201df03ce044c5dfca4dfa9e.jpg)
[190] Addressing electrode passivation in lithium–sulfur batteries by site‐selective morphology‐controlled Li2S formation [EcoMat, 6, e12438 (2024)]Ilju Kim, Jinkwan Jung, Sejin Kim, Hannah Cho, Hyunwon Chu, Wonhee Jo, Dongjae Shin, Hyeokjin Kwon, Hee‐Tak Kim*
https://doi.org/10.1002/eom2.12483 -
![Designing a Schottky Barrier-Free Interface for a Highly Conductive Anode in Proton Exchange Membrane Water Electrolysis [ACS nano, 18, 23331 (2024)]](/files/boards/board_publications/67d9ed359468599f6c47cd6e78d539d6.PNG)
[189] Designing a Schottky Barrier-Free Interface for a Highly Conductive Anode in Proton Exchange Membrane Water Electrolysis [ACS nano, 18, 23331 (2024)]Gisu Doo, Hanmin Bae, Jeesoo Park, Jonghyun Hyun, Ilju Kim, Dong Wook Lee, Euntaek Oh, Hee-Tak Kim*
https://pubs.acs.org/doi/10.1021/acsnano.4c06373 -
![Versatile Zn hosting Lewis-basic interfacial layer for high-performant Zn reversibility in aqueous Zn ion battery [Energy Storage Materials, 71, 103580 (2024)]](/files/boards/board_publications/07ea76db1ea59819e9f48419a3ef5bb7.PNG)
[188] Versatile Zn hosting Lewis-basic interfacial layer for high-performant Zn reversibility in aqueous Zn ion battery [Energy Storage Materials, 71, 103580 (2024)]Jiyun Heo, Youngil Roh, Kyungjae Shin, Changmin Lee, Chunsheng Wang*, Hee-Tak Kim*
https://doi.org/10.1016/j.ensm.2024.103580 -
![Postmortem 7Li NMR analysis for assessing the reversibility of lithium metal electrodes in lithium metal batteries [Journal of Energy Chemistry, 94, 430 (2024)]](/files/boards/board_publications/da5547ae768b9393ff80a54dcf70643f.jpg)
[187] Postmortem 7Li NMR analysis for assessing the reversibility of lithium metal electrodes in lithium metal batteries [Journal of Energy Chemistry, 94, 430 (2024)]Jaewon Baek, Sunha Kim, Hee-Tak Kim*, Oc Hee Han*
https://doi.org/10.1016/j.jechem.2024.02.063 -
![Preferential Lithium Plating in the Interfacial Void Region in All-Solid-State Batteries via Pressure Gradient-Driven Lithium-Ion Flux [ACS Energy Letters, 9, 1035 (2024)]](/files/boards/board_publications/d8c12a89c1686ea6e3979080964836ea.gif)
[186] Preferential Lithium Plating in the Interfacial Void Region in All-Solid-State Batteries via Pressure Gradient-Driven Lithium-Ion Flux [ACS Energy Letters, 9, 1035 (2024)]Dongjae Shin, Jinkwan Jung, Youngil Roh, Changhoon Park, Il Ju Kim, Hyeokjin Kwon, Jaewon Baek, Wonsik Oh, Junhyuk Kim, Seoyoung Jeong, Jaemin Hwang, Yesom Kim, Duk Hyoung Yoon, Hee-Tak Kim*
https://pubs.acs.org/doi/10.1021/acsenergylett.4c00297 -
![Potential-Dependent Ionomer Rearrangement on the Pt Surface in Polymer Electrolyte Membrane Fuel Cells [ACS Applied Materials & Interfaces, 16, 4637 (2024)]](/files/boards/board_publications/e87a1135fd0930dd11e4c88066d5b9d4.gif)
[185] Potential-Dependent Ionomer Rearrangement on the Pt Surface in Polymer Electrolyte Membrane Fuel Cells [ACS Applied Materials & Interfaces, 16, 4637 (2024)]Dong Wook Lee, Jonghyun Hyun, Euntaek Oh, Kyunghwa Seok, Hanmin Bae, Jeesoo Park, Hee-Tak Kim*
https://pubs.acs.org/doi/10.1021/acsami.3c15827 -
![Functionalized metal–organic framework modified membranes with ultralong cyclability and superior capacity for zinc/bromine flowless batteries [Journal of Materials Chemistry A, 12, 13970 (2024)]](/files/boards/board_publications/1ef1384079322f587ec0972fad134055.PNG)
[184] Functionalized metal–organic framework modified membranes with ultralong cyclability and superior capacity for zinc/bromine flowless batteries [Journal of Materials Chemistry A, 12, 13970 (2024)]Dabin Han, Kyungjae Shin, Hee-Tak Kim, Sangaraju Shanmugam*
https://doi.org/10.1039/d4ta01005a -
![High-Entropy Polymer Electrolytes Derived from Multivalent Polymeric Ligands for Solid-State Lithium Metal Batteries with Accelerated Li+ Transport [Nano Letters, 24, 6850 (2024)]](/files/boards/board_publications/a9a9858e0d821eb794c10883f4ccfaaa.PNG)
[183] High-Entropy Polymer Electrolytes Derived from Multivalent Polymeric Ligands for Solid-State Lithium Metal Batteries with Accelerated Li+ Transport [Nano Letters, 24, 6850 (2024)]Fangmin Ye*, Zhixin Wang, Mengcheng Li, Jing Zhang, Dong Wang, Meinan Liu, Aiping Liu*, Hongzhen Lin, Hee-Tak Kim*, Jian Wang*
https://pubs.acs.org/doi/10.1021/acs.nanolett.4c00154 -
![Borate–pyran lean electrolyte-based Li-metal batteries with minimal Li corrosion [Nature Energy, 9, 57 (2024)]](/files/boards/board_publications/2476b03b3c152de63e457df70c9b4fcd.png)
[182] Borate–pyran lean electrolyte-based Li-metal batteries with minimal Li corrosion [Nature Energy, 9, 57 (2024)]H. Kwon, H. Kim, J. Hwang, W. Oh, Y. Roh, D. Shin, H.-T. Kim*
https://doi.org/10.1038/s41560-023-01405-6 -
![Anode reinforcement by polydopamine glue in anion exchange membrane water electrolysis [ACS Energy Letters (2023)]](/files/boards/board_publications/6bce65820f9037188db382f76dc17c87.jpeg)
[181] Anode reinforcement by polydopamine glue in anion exchange membrane water electrolysis [ACS Energy Letters (2023)]J. Hyun, G. Doo, E. Oh, D. W. Lee, K. Seok, H. Bae, J. Park, H.-T. Kim*
https://doi.org/10.1021/acsenergylett.3c02205 -
![The Ionomer–carbon interaction: a key parameter to the power performance of anion exchange membrane fuel cell [J. Electrochem. Soc., 170, 114515 (2023)]](/files/boards/board_publications/5b7cda2958b5be0b86af535b946bb3f0.jpg)
[180] The Ionomer–carbon interaction: a key parameter to the power performance of anion exchange membrane fuel cell [J. Electrochem. Soc., 170, 114515 (2023)]J. Hyun, S.H. Yang, G. Doo, D.W. Lee, E. Oh, M.S. Cha, J. Lee, H.-T. Kim*
https://doi.org/10.1149/1945-7111/ad0a7e -
![Dual functionalities of a Rb+ in lithium sulfur batteries: enhancing polysulfides-reduction-kinetics and Li metal stability [Energy Storage Materials, 63, 103040 (2023)]](/files/boards/board_publications/40d3e03607bba357fffe61f3657272cf.jpg)
[179] Dual functionalities of a Rb+ in lithium sulfur batteries: enhancing polysulfides-reduction-kinetics and Li metal stability [Energy Storage Materials, 63, 103040 (2023)]J. Jung, I.J. Kim, S. Kim, H. Kwon, H. Cho, W. Jo, and H.-T. Kim*
https://doi.org/10.1016/j.ensm.2023.103040 -
![Powering the hydrogen future: Current status and challenges of anion exchange membrane fuel cells [Energy and Environmental Science, 16, 5633 (2023)]](/files/boards/board_publications/f22228e024e67ad5a94b2d9048c74f9a.gif)
[178] Powering the hydrogen future: Current status and challenges of anion exchange membrane fuel cells [Energy and Environmental Science, 16, 5633 (2023)]J. Hyun, H.T. Kim*
https://doi.org/10.1039/D3EE01768K
Publications
Total : 197